FR2845487A1 - Light collection system, especially for use with an optical spectrometer system has first and second mirrors that respectively collect the light emitted from the source and focus it on the second mirror and a detector - Google Patents

Abstract

Light collection system collects the light emitted by a light source (52) and focuses it on a detection device (54). Optimally the system comprises a first mirror (58) that collects the light emitted by the source and focuses it on a second mirror (60), which in turn focuses in on the device.

Description

LIGHT COLLECTION SYSTEM, AMPLIFIER,

  ACHROMATIC AND REDUCED ABSORPTION, ESPECIALLY

  SUITABLE FOR OPTICAL SPECTROMETRIC ANALYSIS

DESCRIPTION

TECHNICAL AREA

  The present invention relates to a light collection system. It applies in particular to

optical spectrometric analysis.

  More specifically, the present invention relates, in the field of optical paths, to a combination of mirrors of different technical characteristics. These mirrors are associated in a particular system which constitutes an optical system for

  collect light from a light source and send it to a light detection device, which can be used at least in the context of optical spectrometric analysis, or even in other optical applications.

  Figure 1 schematically illustrates a

  light collection system 2, placed between a light source 4 and a light detecting device 6 which is pierced with a light entry slot 8. The light path has reference 10.

STATE OF THE PRIOR ART

  At present, the light collection systems used depend on: the nature of the incident light, that is to say the wavelengths of the light radiation composing this incident light, the distance separating the light source from the device detection, and - the dimensions and shape of the

  light source and detection device.

  There are various optical systems adapted to a polychromatic light source whose size ranges from a few millimeters to a few tens of millimeters and which is situated at a distance ranging from a few millimeters to several tens of millimeters.

  centimeters of the detection device.

  For example, for a detection device where the light can penetrate only through a small slot called "entrance slot", having a few millimeters long by a few micrometers wide, the current light transmission and collection systems are consisting of either a parallel-faced blade or a planconvex or biconvex focusing lens or a set of two

  plano-convex focusing lenses.

  FIG. 2 shows the path 12 of light in the case of a light transmission system consisting of a parallel-faced blade 14. The

  references 16, 18, 20, 22 and 23 respectively represent the light source, the detection device, the entry slot of the latter, the path of the light and the light brush which enters the detection device.

  Figure 3 shows the path 24 of light in the case of a light collection system

  consisting of a biconvex focusing lens 26.

  FIG. 4 shows the path 28 of the light in the case of a light collection system consisting of a set of two lenses of

  plane-convex focus 30 and 32.

  The system of FIG. 2 transmits the light without focusing it, that is, without amplifying the light flux. The systems of FIGS. 3 and 4 collect the maximum of light from the source 16 before focusing, that is to say, concentrating, this light on the input slot 20 of the detection device 18 by amplifying the luminous flux. In the case where the light collection system is further away from the detection device than the light source, the system which implements a set of lenses (FIG. 4) makes it possible to transmit the light in a substantially parallel beam between the two. 20 lenses 30 and 32 and therefore minimize the risks of

  poor focus on the entrance slit 20.

  Although the light collection systems of FIGS. 3 and 4 amplify the light fluxes, these systems have the following drawbacks: 1) They do not allow a transmission

  optimal light. Indeed, the optical elements (parallel-sided blade or lenses) more or less absorb the light radiation, according to the wavelength of the latter.

  This absorption is sometimes negligible, particularly in the case of visible light passing through for example a magnesium fluoride lens. This absorption is often greater for far ultraviolet radiation (corresponding to wavelengths).

less than 20Onm).

  By way of example, in the case of 120 nm wavelength radiation, about 80% of the incident light flux is absorbed by a 1.4 mm thick magnesium fluoride lens. Similarly, the absorption can be significant beyond 800nm

(infrared domain).

  2) They do not make it possible to focus at one and the same point all the radiations of different wavelengths that make up a polychromatic light because of the presence of chromatic aberrations, in particular longitudinal aberrations. The consequence of these chromatic aberrations is the dispersion of focus points along the optical axis, depending on

  the wavelength of the radiation.

  This phenomenon is due to variations in the refractive index of the material constituting the light collection system as a function of the wavelength of the incident light. The formation of longitudinal chromatic aberrations for a polychromatic light passing through a magnesium fluoride lens 34 is shown by way of example on

Figure 5.

  In this FIG. 5, the references 36, 38, 42, 44, 46 and 48 respectively represent the polychromatic incident light, the focal point of the light having the lowest wavelength, the focal point of the light having the highest wavelength, the detection device, the entry slot of this detection device, the image spot for the weakest wavelength and the spot

  image for the highest wavelength.

  Figure 5 shows the partial blanking

  thus existing at the entrance slit.

  This problem of focus point

  The difference in wavelength is all the greater when the range of wavelengths observed is wide and induces a difference in sensitivity of the detection device as a function of the wavelengths.

  Indeed, for example, for two light rays of different wavelengths, the luminous flux is not the same for each of the wavelengths at a given position on the optical axis. It can be maximum if the input slot is placed on the focus point of one of the two wavelengths, but it is obligatorily more

  low for the second wavelength.

  In summary, if the known light collection systems, including lenses of

  focusing, partly meet the needs for amplification of light fluxes, they do not maximize this amplification simultaneously for all wavelengths of a polychromatic light.

  This is due, on the one hand, to the absorption, sometimes important, of the light induced by the material constituting the lens and, on the other hand, to the longitudinal chromatic aberrations (differences between the positions, on the optical axis , maxima

luminous flow).

EXPOSURE OF THE INVENTION

  The object of the present invention is to overcome the foregoing disadvantages.

  It relates to an optical system that is capable of solving both light absorption problems and chromatic aberration problems while meeting the needs for amplification of light fluxes (of all types and lengths of light). waves) between one or more light sources

  and one or more detection devices.

  Specifically, the present invention relates to a light collection system, which system is intended to collect the light emitted by at least one light source and to focus the light collected on at least one light detection device, system being characterized in that it comprises at least two mirrors, namely first and second mirrors, the first mirror being able to collect the light emitted by the light source and to focus the light collected on the second mirror, this second mirror mirror being able to focus the light it receives from the first mirror on the light detection device, this system being an amplifier,

  achromatic and reduced absorption.

  The light detection device can

  have an entrance slot or not.

  According to a first particular embodiment of the system which is the subject of the invention, the first and second mirrors have the same axis, this same axis constituting the optical axis of the system, and the respective foci of the first and second mirrors are located

on this optical axis.

  These respective foci of the first and second mirrors may be confused or, at

contrary, distinct.

  In the case of this first particular embodiment, the first mirror may comprise a central bore which is capable of allowing the light focused by the second mirror to pass through.

  the light detection device.

  According to a second particular embodiment, the first and second mirrors are offset with respect to each other, at least one of the first and second mirrors being off axis. Each of the first and second mirrors may be selected from spherical mirrors, mirrors

  parabolic and ellipsoidal mirrors.

  Each of the first and second mirrors can

  be covered with a metallic or chemical deposit.

  The light detection device can

  comprise an entrance slot and the second mirror is then provided to focus the light it receives from the first mirror on this entrance slot.

  The light detection device may be an optical spectrometric analysis device comprising an input slot and the second mirror is then provided to focus the light it receives from the first mirror on this input slot.

BR VE DESCRIPTION OF THE DRAWINGS

  The present invention will be better understood at

  reading the description of exemplary embodiments given below, for information only and

  in no way limiting, with reference to the accompanying drawings, in which: - Figure 1 schematically illustrates a light collection system placed between a light source and a light detection device and has already been described; - Figure 2 illustrates schematically the path of light in the case of a known light transmission system, consisting of a parallel-faced plate, and has already been described; FIG. 3 schematically illustrates the path of light in the case of a known light transmission system, consisting of a biconvex focusing lens, and has already been described; - Figure 4 schematically illustrates the path of light in the case of a known light transmission system, consisting of a set of two plano-convex focusing lenses, and has already been described, - Figure 5 schematically illustrates the partial closure that exists at the slot of 3 and 4, for a polychromatic light, and has already been described, FIG. 6 is a schematic view of a first particular embodiment of the optical system which is the subject of the invention, using two mirrors placed on the optical axis, in the case of a light source 10 which is large relative to the size of these mirrors, - Figure 7 is a schematic view of a second particular embodiment of the optical system object of the invention, using two mirrors 15 placed on the optical axis, in the case of a light source which is small compared to the size of these mirrors, - Figure 8 is a schematic view of a third mode of particular embodiment of the optical system object of the invention, using two mirrors of which at least one is off axis, - Figure 9 schematically illustrates the transmission of light in an installation comprising a source of lumi 25, a mirror light collection system in accordance with the invention and a light detection device constituted by an optical emission spectrometer, and FIG. 10 is a schematic view of another system. according to the invention, using more than

two mirrors.

  EXPOSURE OF PARTICULAR RESTORATION MODES

  In an optical system according to the invention, two mirrors are preferably used, respectively called "first mirror" and "second mirror". The shapes and characteristics of these two mirrors are predefined and one can form, or not,

  on these mirrors, a metallic or chemical deposit.

  This metallic or chemical deposit is intended to protect the mirror on which it is formed against possible mechanical or chemical attacks and to

  minimize the absorption of light radiation.

  The first mirror is provided to collect the maximum of light from the light source, after which the optical system is placed, and to focus the light so collected on the second mirror. This second mirror then focuses the light it receives on the device of

  light detection that follows the optical system.

  This device usually includes a

  entrance slot and the second mirror then allows to focus the light it receives on this slot. In a preferred application of the invention, this device is an optical emission spectrometer which effectively has such a slot.

  The size of the mirrors is a function of the power and the size of the light source, the distance between the latter and the mirrors and the distance between them and the detection device or, more precisely, the slot of this device . The first and second mirrors are focusing, which amplifies the luminous flux. In addition, the use of the first and second mirrors, instead of lenses, solves the

  light absorption problems mentioned above.

  Problems of chromatic aberration

  are, in turn, solved through the use of mirrors, which are inherently devoid of chromatic effects.

  As a first mirror, a spherical, parabolic or ellipsodal mirror is preferably used. It is the same for the second mirror.

  When the two mirrors have the same axis 15 and their respective focal points or focal points are placed on the same axis constituting the optical axis of the system, the first mirror may be pierced with a hole to allow the passage of the light from the second mirror towards the light detection device (in the case of the examples of FIGS.

and 10).

  In the case where the two mirrors are offset relative to each other, to constitute an off-axis assembly, it is not necessary that the first mirror be pierced (case of

the example of Figure 8).

  Let's go back to the examples in Figures 6 to 8.

  The optical system 50 according to the invention, which is schematically shown in FIG. 6, is placed between a light source 52 and a light detection device 54 whose slot

input to reference 56.

  The first mirror 58 of the system 50 is concave while the second mirror 60 of this system 5 is convex. The light 62 emitted by the source 52 is picked up by the mirror 58 and focused by the latter towards the mirror 60 which focuses it in turn on the

slot 56.

  In the example of Figure 6, the size of the light source 52 is comparable to that of the mirrors 58 and 60. However, it could be larger. The optical axis of the system 50 has the reference X1. It can be seen that the mirror 58 is much larger than the mirror 60, is located between the mirror and the device 54 and has a bore 64 allowing the passage of light that the mirror 60

focuses on the slot 56.

  In addition, the mirrors 58 and 60 are of the spherical type for example, have the same axis which coincides with the axis Xi and their respective foci F1 and F2 are on this axis X1. The focal lengths of the mirrors 58 and 60 are respectively denoted d1 and d2, with d1 greater than d2. The foci F1 and F2 are distinct in the example of FIG.

  be confused in other examples.

  The optical system 66 according to the invention, which is schematically shown in FIG. 7, is placed between a light source 68 and a light detection device 70 whose slot

entry to reference 72.

  The first mirror 74 of the system 66 is concave while the second mirror 76 of this system is convex. The light 78 emitted by the source 68 is picked up by the mirror 74 and focused by the latter towards the mirror 76 which focuses it in turn on the

slot 72.

  In the example of FIG. 7, the size of the light source 68 is small relative to the size of the mirrors 74 and 76. It can be, for example, 16 times smaller.

  The optical axis of the system 66 has the reference X2. It can be seen that the mirror 74 is much larger than the mirror 76, is located between the mirror 76 and the device 70 and has a bore 80 permitting the passage of light that the mirror 76

focuses on the slot 72.

  In addition, the mirrors 74 and 76 are of the spherical type for example, have the same axis which coincides with the axis X2 and their respective foci F3 and F4 are on this axis X2. The focal lengths of the mirrors 74 and 76 are respectively denoted d3 and d4, with d3 greater than d4. The F3 and F4 foci are distinct in the example of Figure 7 but could

  be confused in other examples.

  The optical system 80 according to the invention, which is schematically shown in FIG. 8, is placed between a light source 82 and a light detection device 84 whose slot

input to reference 86.

  The first mirror 88 of the system 80 is concave while the second mirror 90 of this system is convex. The light 92 emitted by the source 82 is picked up by the mirror 88 and focused by the mirror 88 towards the mirror 90 which focuses it in turn on the

slot 86.

  It can be seen that the mirror 88 is much larger than the mirror 90. The two mirrors 88 and 90 are offset relative to each other and off axis ("off axis") with respect to the optical axis . In addition, the mirrors 74 and 76 are of the spherical type, for example, and their respective foci coincide at the same point F. The focal lengths of the mirrors 74 and 76 are respectively denoted d5 and d6, with d5 greater than d6. Thus, any polychromatic light emitted by any of the sources 52, 68 and 82 is focused on the input slot of the light source.

  corresponding light detection.

  An example of application of the invention is now given purely by way of indication and in no way limitative: the case of

  glow discharge optical emission spectrometry, applied to the spectrometric analysis of emission lines, for example emission lines of carbon, hydrogen, oxygen and nitrogen, which are between 120nm and 160nm.

  The examples given above (FIGS. 6 to 8) can be applied to the case where the optical system is used to optimize the collection of the light coming from a cell, or lamp, with a glow discharge (constituting the light source). direction of a wavelength dispersive optical spectrometer

  (constituting the detection system).

  This type of light source emits a polychromatic light whose radiation, after having penetrated into the detection system, is

  dispersed according to their wavelengths.

  Referring to FIG. 9, a glow discharge lamp 94, an optical emission spectrometer 96, which is wavelength dipersive, and a mirror light collection system 98, in accordance with FIG. the invention. The path followed by light in the set 94-96-98 of Figure 9

reference 100.

  The use of mirrors makes it possible to amplify the luminous fluxes and in particular to solve the abovementioned problems of absorption and chromatic aberration. The assembly 94-96-98 of FIG. 9 can be used for the respective wavelengths 121, 557 nm, 130, 217 nm, 149/262 nm and 156, 144 nm, respectively emitted by the elements hydrogen, oxygen, nitrogen and carbon. during their radiative de-excitation within the cell at

glow discharge.

  Embodiments of a system according to the invention are schematically illustrated

  in FIG. 9: the optical system 98 can process, in addition to the light coming from the source 94, the light which comes from another light source 102 and to which the same path 100 is imposed by means of a mirror 30 semi -Transparent 104 adapted to the lights considered.

  In addition, it is possible to process the light or lights coming from the optical system 98 by a

  spectrometer 106, in addition to the spectrometer 96.

  An appropriate semi-transparent mirror 108 is then provided to send the light or lights from the system 98 to the slot 110 of the spectrometer 106.

  The use of a light collection system according to the invention makes it possible to maximize the light flux transmitted from the light source to the detection system by this light collection system (amplification). the absorption of light radiation by the optical elements, and - to focus all the radiations of different wavelengths at the same point (achromatism). The system which is the subject of the invention is

  capable of providing considerable gains in terms of transmitted and collected light flux and in terms of simultaneously observable spectral domains.

  It can be used with all

  known light detection devices.

  It is not limited to use in

  the ultraviolet domain of light radiation.

  In addition, it is not limited to use with a glow discharge lamp but

  can be used with any light source.

  This system is not limited to a number of

  mirrors equal to two (see the description in Figure 10).

  In addition, it is not limited to the use of spherical mirrors,

parabolic or ellipsodal.

  Nor is it limited to the spectrometric analysis of the elements C, H, O and N: it also applies to the spectrometric analysis of any

chemical element.

  FIG. 10 is an alternative embodiment of FIG. 6, in which, in addition to the mirrors 58 and 60, another mirror 112 is used to reflect light coming from the system 50

towards the slot 56 of the device 54.

Such an arrangement is for example

  usable when this device can not be placed in alignment with the source 52.

Claims (10)

  An optical light collecting system, the system (50, 66, 80) being for collecting light emitted from at least one light source (52, 68, 82, 94, 102) and focusing the light collected on at least one light detection device (54, 70, 84, 96, 106), this system being characterized in that it comprises at least two mirrors, namely first and second mirrors, the first mirror (58, 74, 88) being able to collect the light emitted by the light source and to focus the light collected on the second mirror, this second mirror (60, 76, 90) being able to focus the light it receives from the first mirror on the light detection device, this system thus being an amplifier,   achromatic and reduced absorption.   The system of claim 1, wherein the first and second mirrors (58, 60; 74, 76) have the same axis (X1; X2), the same axis constituting the optical axis of the system, and the respective foci. (F1, F2, F3, F4) of the first and second mirrors are located on this optical axis.   The system of claim 2, wherein the respective foci (F1, F2, F3, F4) of   first and second mirrors are confused.   The system of claim 2, wherein the respective foci (F1, F2, F3, F4) of   first and second mirrors are distinct.   5. System according to any one of   Claims 2 to 4, wherein the first mirror has a central bore (64, 80) which is adapted to let the light focused by the second   mirror towards the light detection device.   6. System according to claim 1, wherein the first and second mirrors (88, 90) are offset relative to each other, at least one of the first and second mirrors being off axis. 15 7. System according to any one of   Claims 1 to 6, wherein each of the first and second mirrors (58, 74, 88; 60, 76, 90) is selected from spherical mirrors, parabolic mirrors, and elliptical mirrors.   8. System according to any one of   Claims 1 to 7, wherein each of the first and second mirrors (58, 74, 88, 60, 76, 90) is covered with a metal or chemical deposit.   9. System according to any one of   Claims 1 to 8, wherein the light detecting device comprises an entrance slot (56, 72, 86, 110) and the second mirror is provided for   focus the light it receives from the first mirror on this entrance slot.   The system of any one of claims 1 to 8, wherein the device of   Light detection is an optical spectrometric analysis device (96) comprising an input slot and the second mirror is provided to focus the light it receives from the first mirror on this input slot.